/*
 * VARCem   Virtual ARchaeological Computer EMulator.
 *          An emulator of (mostly) x86-based PC systems and devices,
 *          using the ISA,EISA,VLB,MCA  and PCI system buses, roughly
 *          spanning the era between 1981 and 1995.
 *
 *          Implementation of a generic IDE-XTA disk controller.
 *
 *          XTA is the acronym for 'XT-Attached', which was basically
 *          the XT-counterpart to what we know now as IDE (which is
 *          also named ATA - AT Attachment.)  The basic ideas was to
 *          put the actual drive controller electronics onto the drive
 *          itself, and have the host machine just talk to that using
 *          a simpe, standardized I/O path- hence the name IDE, for
 *          Integrated Drive Electronics.
 *
 *          In the ATA version of IDE, the programming interface of
 *          the IBM PC/AT (which used the Western Digitial 1002/1003
 *          controllers) was kept, and, so, ATA-IDE assumes a 16bit
 *          data path: it reads and writes 16bit words of data. The
 *          disk drives for this bus commonly have an 'A' suffix to
 *          identify them as 'ATBUS'.
 *
 *          In XTA-IDE, which is slightly older, the programming
 *          interface of the IBM PC/XT (which used the MFM controller
 *          from Xebec) was kept, and, so, it uses an 8bit data path.
 *          Disk drives for this bus commonly have the 'X' suffix to
 *          mark them as being for this XTBUS variant.
 *
 *          So, XTA and ATA try to do the same thing, but they use
 *          different ways to achive their goal.
 *
 *          Also, XTA is **not** the same as XTIDE.  XTIDE is a modern
 *          variant of ATA-IDE, but retro-fitted for use on 8bit XT
 *          systems: an extra register is used to deal with the extra
 *          data byte per transfer.  XTIDE uses regular IDE drives,
 *          and uses the regular ATA/IDE programming interface, just
 *          with the extra register.
 *
 * NOTE:    This driver implements both the 'standard' XTA interface,
 *          sold by Western Digital as the WDXT-140 (no BIOS) and the
 *          WDXT-150 (with BIOS), as well as some variants customized
 *          for specific machines.
 *
 * NOTE:    The XTA interface is 0-based for sector numbers !!
 *
 *
 *
 * Authors: Fred N. van Kempen, <decwiz@yahoo.com>
 *
 *          Based on my earlier HD20 driver for the EuroPC.
 *
 *          Copyright 2017-2018 Fred N. van Kempen.
 *
 *          Redistribution and  use  in source  and binary forms, with
 *          or  without modification, are permitted  provided that the
 *          following conditions are met:
 *
 *          1. Redistributions of  source  code must retain the entire
 *             above notice, this list of conditions and the following
 *             disclaimer.
 *
 *          2. Redistributions in binary form must reproduce the above
 *             copyright  notice,  this list  of  conditions  and  the
 *             following disclaimer in  the documentation and/or other
 *             materials provided with the distribution.
 *
 *          3. Neither the  name of the copyright holder nor the names
 *             of  its  contributors may be used to endorse or promote
 *             products  derived from  this  software without specific
 *             prior written permission.
 *
 * THIS SOFTWARE  IS  PROVIDED BY THE  COPYRIGHT  HOLDERS AND CONTRIBUTORS
 * "AS IS" AND  ANY EXPRESS  OR  IMPLIED  WARRANTIES,  INCLUDING, BUT  NOT
 * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A
 * PARTICULAR PURPOSE  ARE  DISCLAIMED. IN  NO  EVENT  SHALL THE COPYRIGHT
 * HOLDER OR  CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
 * SPECIAL,  EXEMPLARY,  OR  CONSEQUENTIAL  DAMAGES  (INCLUDING,  BUT  NOT
 * LIMITED TO, PROCUREMENT OF SUBSTITUTE  GOODS OR SERVICES;  LOSS OF USE,
 * DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED  AND ON  ANY
 * THEORY OF  LIABILITY, WHETHER IN  CONTRACT, STRICT  LIABILITY, OR  TORT
 * (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING  IN ANY  WAY OUT OF THE USE
 * OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
 */
#include <stdarg.h>
#include <stdint.h>
#include <stdio.h>
#include <string.h>
#include <stdlib.h>
#include <wchar.h>
#define HAVE_STDARG_H
#include <86box/86box.h>
#include <86box/io.h>
#include <86box/dma.h>
#include <86box/pic.h>
#include <86box/mem.h>
#include <86box/rom.h>
#include <86box/device.h>
#include <86box/timer.h>
#include <86box/plat.h>
#include <86box/ui.h>
#include <86box/hdc.h>
#include <86box/hdd.h>

#define HDC_TIME           (250 * TIMER_USEC)

#define WD_REV_1_BIOS_FILE "roms/hdd/xta/idexywd2.bin"
#define WD_REV_2_BIOS_FILE "roms/hdd/xta/infowdbios.rom"

enum {
    STATE_IDLE = 0,
    STATE_RECV,
    STATE_RDATA,
    STATE_RDONE,
    STATE_SEND,
    STATE_SDATA,
    STATE_SDONE,
    STATE_COMPL
};

/* Command values. */
#define CMD_TEST_READY  0x00
#define CMD_RECALIBRATE 0x01
/* unused     0x02 */
#define CMD_READ_SENSE       0x03
#define CMD_FORMAT_DRIVE     0x04
#define CMD_READ_VERIFY      0x05
#define CMD_FORMAT_TRACK     0x06
#define CMD_FORMAT_BAD_TRACK 0x07
#define CMD_READ_SECTORS     0x08
/* unused    0x09 */
#define CMD_WRITE_SECTORS       0x0a
#define CMD_SEEK                0x0b
#define CMD_SET_DRIVE_PARAMS    0x0c
#define CMD_READ_ECC_BURST      0x0d
#define CMD_READ_SECTOR_BUFFER  0x0e
#define CMD_WRITE_SECTOR_BUFFER 0x0f
#define CMD_RAM_DIAGS           0xe0
/* unused    0xe1 */
/* unused    0xe2 */
#define CMD_DRIVE_DIAGS 0xe3
#define CMD_CTRL_DIAGS  0xe4
#define CMD_READ_LONG   0xe5
#define CMD_WRITE_LONG  0xe6

/* Status register (reg 1) values. */
#define STAT_REQ 0x01 /* controller needs data transfer */
#define STAT_IO  0x02 /* direction of transfer (TO bus) */
#define STAT_CD  0x04 /* transfer of Command or Data */
#define STAT_BSY 0x08 /* controller is busy */
#define STAT_DRQ 0x10 /* DMA requested */
#define STAT_IRQ 0x20 /* interrupt requested */
#define STAT_DCB 0x80 /* not seen by driver */

/* Sense Error codes. */
#define ERR_NOERROR  0x00 /* no error detected */
#define ERR_NOINDEX  0x01 /* drive did not detect IDX pulse */
#define ERR_NOSEEK   0x02 /* drive did not complete SEEK */
#define ERR_WRFAULT  0x03 /* write fault during last cmd */
#define ERR_NOTRDY   0x04 /* drive did not go READY after cmd */
#define ERR_NOTRK000 0x06 /* drive did not see TRK0 signal */
#define ERR_LONGSEEK 0x08 /* long seek in progress */
#define ERR_IDREAD   0x10 /* ECC error during ID field */
#define ERR_DATA     0x11 /* uncorrectable ECC err in data */
#define ERR_NOMARK   0x12 /* no address mark detected */
#define ERR_NOSECT   0x14 /* sector not found */
#define ERR_SEEK     0x15 /* seek error */
#define ERR_ECCDATA  0x18 /* ECC corrected data */
#define ERR_BADTRK   0x19 /* bad track detected */
#define ERR_ILLCMD   0x20 /* invalid command received */
#define ERR_ILLADDR  0x21 /* invalid disk address received */
#define ERR_BADRAM   0x30 /* bad RAM in sector data buffer */
#define ERR_BADROM   0x31 /* bad checksum in ROM test */
#define ERR_BADECC   0x32 /* ECC polynomial generator bad */

/* Completion Byte fields. */
#define COMP_DRIVE 0x20
#define COMP_ERR   0x02

#define IRQ_ENA    0x02
#define DMA_ENA    0x01

/* The device control block (6 bytes) */
#pragma pack(push, 1)
typedef struct dcb_t {
    uint8_t cmd; /* [7:5] class, [4:0] opcode    */

    uint8_t head   : 5; /* [4:0] head number        */
    uint8_t drvsel : 1; /* [5] drive select        */
    uint8_t mbz    : 2; /* [7:6] 00            */

    uint8_t sector   : 6; /* [5:0] sector number 0-63    */
    uint8_t cyl_high : 2; /* [7:6] cylinder [9:8] bits    */

    uint8_t cyl_low; /* [7:0] cylinder [7:0] bits    */

    uint8_t count; /* [7:0] blk count / interleave    */

    uint8_t ctrl; /* [7:0] control field        */
} dcb_t;
#pragma pack(pop)

/* The (configured) Drive Parameters. */
#pragma pack(push, 1)
typedef struct dprm_t {
    uint8_t cyl_high; /* (MSB) number of cylinders */
    uint8_t cyl_low;  /* (LSB) number of cylinders */
    uint8_t heads;    /* number of heads per cylinder */
    uint8_t rwc_high; /* (MSB) reduced write current cylinder */
    uint8_t rwc_low;  /* (LSB) reduced write current cylinder */
    uint8_t wp_high;  /* (MSB) write precompensation cylinder */
    uint8_t wp_low;   /* (LSB) write precompensation cylinder */
    uint8_t maxecc;   /* max ECC data burst length */
} dprm_t;
#pragma pack(pop)

/* Define an attached drive. */
typedef struct drive_t {
    int8_t id;   /* drive ID on bus */
    int8_t present; /* drive is present */
    int8_t hdd_num; /* index to global disk table */
    int8_t type;    /* drive type ID */

    uint16_t cur_cyl; /* last known position of heads */

    uint8_t  spt; /* active drive parameters */
    uint8_t  hpc;
    uint16_t tracks;

    uint8_t  cfg_spt; /* configured drive parameters */
    uint8_t  cfg_hpc;
    uint16_t cfg_tracks;
} drive_t;

typedef struct hdc_t {
    const char *name; /* controller name */

    uint16_t base; /* controller base I/O address */
    int8_t   irq;  /* controller IRQ channel */
    int8_t   dma;  /* controller DMA channel */
    int8_t   type; /* controller type ID */

    uint32_t rom_addr; /* address where ROM is */
    rom_t    bios_rom; /* descriptor for the BIOS */

    /* Controller state. */
    int8_t     state;  /* controller state */
    uint8_t    sense;  /* current SENSE ERROR value    */
    uint8_t    status; /* current operational status    */
    uint8_t    intr;
    pc_timer_t timer;

    /* Data transfer. */
    int16_t  buf_idx; /* buffer index and pointer */
    int16_t  buf_len;
    uint8_t *buf_ptr;

    /* Current operation parameters. */
    dcb_t    dcb;    /* device control block */
    uint16_t track;  /* requested track# */
    uint8_t  head;   /* requested head# */
    uint8_t  sector; /* requested sector# */
    uint8_t  comp;   /* operation completion byte */
    int count;       /* requested sector count */

    drive_t drives[XTA_NUM]; /* the attached drive(s) */

    uint8_t data[512];       /* data buffer */
    uint8_t sector_buf[512]; /* sector buffer */
} hdc_t;

#ifdef ENABLE_XTA_LOG
int xta_do_log = ENABLE_XTA_LOG;

static void
xta_log(const char *fmt, ...)
{
    va_list ap;

    if (xta_do_log) {
        va_start(ap, fmt);
        pclog_ex(fmt, ap);
        va_end(ap);
    }
}
#else
#    define xta_log(fmt, ...)
#endif

static void
set_intr(hdc_t *dev)
{
    dev->status = STAT_REQ | STAT_CD | STAT_IO | STAT_BSY;
    dev->state  = STATE_COMPL;

    if (dev->intr & IRQ_ENA) {
        dev->status |= STAT_IRQ;
        picint(1 << dev->irq);
    }
}

/* Get the logical (block) address of a CHS triplet. */
static int
get_sector(hdc_t *dev, drive_t *drive, off64_t *addr)
{
    if (drive->cur_cyl != dev->track) {
        xta_log("%s: get_sector: wrong cylinder %d/%d\n",
                dev->name, drive->cur_cyl, dev->track);
        dev->sense = ERR_ILLADDR;
        return 1;
    }

    if (dev->head >= drive->hpc) {
        xta_log("%s: get_sector: past end of heads\n", dev->name);
        dev->sense = ERR_ILLADDR;
        return 1;
    }

    if (dev->sector >= drive->spt) {
        xta_log("%s: get_sector: past end of sectors\n", dev->name);
        dev->sense = ERR_ILLADDR;
        return 1;
    }

    /* Calculate logical address (block number) of desired sector. */
    *addr = ((((off64_t) dev->track * drive->hpc) + dev->head) * drive->spt) + dev->sector;

    return 0;
}

static void
next_sector(hdc_t *dev, drive_t *drive)
{
    if (++dev->sector >= drive->spt) {
        dev->sector = 0;
        if (++dev->head >= drive->hpc) {
            dev->head = 0;
            dev->track++;
            if (++drive->cur_cyl >= drive->tracks)
                drive->cur_cyl = (drive->tracks - 1);
        }
    }
}

/* Perform the seek operation. */
static void
do_seek(hdc_t *dev, drive_t *drive, int cyl)
{
    dev->track = cyl;

    if (dev->track >= drive->tracks)
        drive->cur_cyl = (drive->tracks - 1);
    else
        drive->cur_cyl = dev->track;
}

/* Format a track or an entire drive. */
static void
do_format(hdc_t *dev, drive_t *drive, dcb_t *dcb)
{
    int     start_cyl;
    int     end_cyl;
    int     start_hd;
    int     end_hd;
    off64_t addr;

    /* Get the parameters from the DCB. */
    if (dcb->cmd == CMD_FORMAT_DRIVE) {
        start_cyl = 0;
        start_hd  = 0;
        end_cyl   = drive->tracks;
        end_hd    = drive->hpc;
    } else {
        start_cyl = (dcb->cyl_low | (dcb->cyl_high << 8));
        start_hd  = dcb->head;
        end_cyl   = start_cyl + 1;
        end_hd    = start_hd + 1;
    }

    switch (dev->state) {
        case STATE_IDLE:
            /* Seek to cylinder. */
            do_seek(dev, drive, start_cyl);
            dev->head   = dcb->head;
            dev->sector = 0;

            /* Activate the status icon. */
            ui_sb_update_icon_write(SB_HDD | HDD_BUS_XTA, 1);

do_fmt:
            /*
             * For now, we don't use the interleave factor (in
             * dcb->count), although we should one day use an
             * image format that can handle it..
             *
             * That said, we have been given a sector_buf of
             * data to fill the sectors with, so we will use
             * that at least.
             */
            for (int h = start_hd; h < end_hd; h++) {
                for (uint8_t s = 0; s < drive->spt; s++) {
                    /* Set the sector we need to write. */
                    dev->head   = h;
                    dev->sector = s;

                    /* Get address of sector to write. */
                    if (get_sector(dev, drive, &addr))
                        break;

                    /* Write the block to the image. */
                    if (hdd_image_write(drive->hdd_num, addr, 1,
                                        (uint8_t *) dev->sector_buf) < 0)
                        dev->sense = ERR_BADTRK;
                }
            }

            /* One more track done. */
            if (++start_cyl == end_cyl)
                break;

            /* This saves us a LOT of code. */
            goto do_fmt;

        default:
            break;
    }

    /* De-activate the status icon. */
    ui_sb_update_icon_write(SB_HDD | HDD_BUS_XTA, 0);
}

/* Execute the DCB we just received. */
static void
hdc_callback(void *priv)
{
    hdc_t        *dev = (hdc_t *) priv;
    dcb_t        *dcb = &dev->dcb;
    drive_t      *drive;
    const dprm_t *params;
    off64_t       addr;
    int           no_data = 0;
    int           val;

    drive     = &dev->drives[dcb->drvsel];
    dev->comp = (dcb->drvsel) ? COMP_DRIVE : 0x00;
    dev->status |= STAT_DCB;

    switch (dcb->cmd) {
        case CMD_TEST_READY:
            if (!drive->present) {
                dev->comp |= COMP_ERR;
                dev->sense = ERR_NOTRDY;
            }
            set_intr(dev);
            break;

        case CMD_RECALIBRATE:
            if (!drive->present) {
                dev->comp |= COMP_ERR;
                dev->sense = ERR_NOTRDY;
            } else {
                dev->track = drive->cur_cyl = 0;
            }
            set_intr(dev);
            break;

        case CMD_READ_SENSE:
            switch (dev->state) {
                case STATE_IDLE:
                    dev->buf_idx    = 0;
                    dev->buf_len    = 4;
                    dev->buf_ptr    = dev->data;
                    dev->buf_ptr[0] = dev->sense;
                    dev->buf_ptr[1] = dcb->drvsel ? 0x20 : 0x00;
                    dev->buf_ptr[2] = (drive->cur_cyl >> 2) | (dev->sector & 0x3f);
                    dev->buf_ptr[3] = (drive->cur_cyl & 0xff);
                    dev->sense      = ERR_NOERROR;
                    dev->status |= (STAT_IO | STAT_REQ);
                    dev->state = STATE_SDATA;
                    break;

                case STATE_SDONE:
                    set_intr(dev);
                    break;

                default:
                    break;
            }
            break;

        case CMD_READ_VERIFY:
            no_data = 1;
            fallthrough;

        case CMD_READ_SECTORS:
            if (!drive->present) {
                dev->comp |= COMP_ERR;
                dev->sense = ERR_NOTRDY;
                set_intr(dev);
                break;
            }

            switch (dev->state) {
                case STATE_IDLE:
                    /* Seek to cylinder. */
                    do_seek(dev, drive,
                            (dcb->cyl_low | (dcb->cyl_high << 8)));
                    dev->head   = dcb->head;
                    dev->sector = dcb->sector;

                    /* Get sector count; count=0 means 256. */
                    dev->count = (int) dcb->count;
                    if (dev->count == 0)
                        dev->count = 256;
                    dev->buf_len = 512;

                    dev->state = STATE_SEND;
                    fallthrough;

                case STATE_SEND:
                    /* Activate the status icon. */
                    ui_sb_update_icon(SB_HDD | HDD_BUS_XTA, 1);
do_send:
                    /* Get address of sector to load. */
                    if (get_sector(dev, drive, &addr)) {
read_error:
                        /* De-activate the status icon. */
                        ui_sb_update_icon(SB_HDD | HDD_BUS_XTA, 0);
                        dev->comp |= COMP_ERR;
                        set_intr(dev);
                        return;
                    }

                    /* Read the block from the image. */
                    if (hdd_image_read(drive->hdd_num, addr, 1,
                                       (uint8_t *) dev->sector_buf) < 0) {
                        dev->sense = ERR_BADTRK;
                        goto read_error;
                    }

                    /* Ready to transfer the data out. */
                    dev->state   = STATE_SDATA;
                    dev->buf_idx = 0;
                    if (no_data) {
                        /* Delay a bit, no actual transfer. */
                        timer_advance_u64(&dev->timer, HDC_TIME);
                    } else {
                        if (dev->intr & DMA_ENA) {
                            /* DMA enabled. */
                            dev->buf_ptr = dev->sector_buf;
                            timer_advance_u64(&dev->timer, HDC_TIME);
                        } else {
                            /* Copy from sector to data. */
                            memcpy(dev->data,
                                   dev->sector_buf,
                                   dev->buf_len);
                            dev->buf_ptr = dev->data;

                            dev->status |= (STAT_IO | STAT_REQ);
                        }
                    }
                    break;

                case STATE_SDATA:
                    if (!no_data) {
                        /* Perform DMA. */
                        while (dev->buf_idx < dev->buf_len) {
                            val = dma_channel_write(dev->dma,
                                                    *dev->buf_ptr);
                            if (val == DMA_NODATA) {
                                xta_log("%s: CMD_READ_SECTORS out of data (idx=%d, len=%d)!\n", dev->name, dev->buf_idx, dev->buf_len);

                                dev->status |= (STAT_CD | STAT_IO | STAT_REQ);
                                timer_advance_u64(&dev->timer, HDC_TIME);
                                return;
                            }
                            dev->buf_ptr++;
                            dev->buf_idx++;
                        }
                    }
                    timer_advance_u64(&dev->timer, HDC_TIME);
                    dev->state = STATE_SDONE;
                    break;

                case STATE_SDONE:
                    dev->buf_idx = 0;
                    if (--dev->count == 0) {
                        /* De-activate the status icon. */
                        ui_sb_update_icon(SB_HDD | HDD_BUS_XTA, 0);

                        set_intr(dev);
                        return;
                    }

                    /* Addvance to next sector. */
                    next_sector(dev, drive);

                    /* This saves us a LOT of code. */
                    dev->state = STATE_SEND;
                    goto do_send;

                default:
                    break;
            }
            break;

        case CMD_WRITE_SECTORS:
            if (!drive->present) {
                dev->comp |= COMP_ERR;
                dev->sense = ERR_NOTRDY;
                set_intr(dev);
                break;
            }

            switch (dev->state) {
                case STATE_IDLE:
                    /* Seek to cylinder. */
                    do_seek(dev, drive,
                            (dcb->cyl_low | (dcb->cyl_high << 8)));
                    dev->head   = dcb->head;
                    dev->sector = dcb->sector;

                    /* Get sector count; count=0 means 256. */
                    dev->count = (int) dev->dcb.count;
                    if (dev->count == 0)
                        dev->count = 256;
                    dev->buf_len = 512;

                    dev->state = STATE_RECV;
                    fallthrough;

                case STATE_RECV:
                    /* Activate the status icon. */
                    ui_sb_update_icon_write(SB_HDD | HDD_BUS_XTA, 1);
do_recv:
                    /* Ready to transfer the data in. */
                    dev->state   = STATE_RDATA;
                    dev->buf_idx = 0;
                    if (dev->intr & DMA_ENA) {
                        /* DMA enabled. */
                        dev->buf_ptr = dev->sector_buf;
                        timer_advance_u64(&dev->timer, HDC_TIME);
                    } else {
                        /* No DMA, do PIO. */
                        dev->buf_ptr = dev->data;
                        dev->status |= STAT_REQ;
                    }
                    break;

                case STATE_RDATA:
                    if (!no_data) {
                        /* Perform DMA. */
                        dev->status = STAT_BSY;
                        while (dev->buf_idx < dev->buf_len) {
                            val = dma_channel_read(dev->dma);
                            if (val == DMA_NODATA) {
                                xta_log("%s: CMD_WRITE_SECTORS out of data (idx=%d, len=%d)!\n", dev->name, dev->buf_idx, dev->buf_len);

                                xta_log("%s: CMD_WRITE_SECTORS out of data!\n", dev->name);
                                dev->status |= (STAT_CD | STAT_IO | STAT_REQ);
                                timer_advance_u64(&dev->timer, HDC_TIME);
                                return;
                            }

                            dev->buf_ptr[dev->buf_idx] = (val & 0xff);
                            dev->buf_idx++;
                        }
                        dev->state = STATE_RDONE;
                        timer_advance_u64(&dev->timer, HDC_TIME);
                    }
                    break;

                case STATE_RDONE:
                    /* Copy from data to sector if PIO. */
                    if (!(dev->intr & DMA_ENA))
                        memcpy(dev->sector_buf, dev->data,
                               dev->buf_len);

                    /* Get address of sector to write. */
                    if (get_sector(dev, drive, &addr)) {
write_error:
                        /* De-activate the status icon. */
                        ui_sb_update_icon_write(SB_HDD | HDD_BUS_XTA, 0);

                        dev->comp |= COMP_ERR;
                        set_intr(dev);
                        return;
                    }

                    /* Write the block to the image. */
                    if (hdd_image_write(drive->hdd_num, addr, 1,
                                        (uint8_t *) dev->sector_buf) < 0) {
                        dev->sense = ERR_BADTRK;
                        goto write_error;
                    }

                    dev->buf_idx = 0;
                    if (--dev->count == 0) {
                        /* De-activate the status icon. */
                        ui_sb_update_icon_write(SB_HDD | HDD_BUS_XTA, 0);

                        set_intr(dev);
                        return;
                    }

                    /* Advance to next sector. */
                    next_sector(dev, drive);

                    /* This saves us a LOT of code. */
                    dev->state = STATE_RECV;
                    goto do_recv;

                default:
                    break;
            }
            break;

        case CMD_FORMAT_DRIVE:
        case CMD_FORMAT_TRACK:
            if (drive->present) {
                do_format(dev, drive, dcb);
            } else {
                dev->comp |= COMP_ERR;
                dev->sense = ERR_NOTRDY;
            }
            set_intr(dev);
            break;

        case CMD_SEEK:
            /* Seek to cylinder. */
            val = (dcb->cyl_low | (dcb->cyl_high << 8));
            if (drive->present) {
                do_seek(dev, drive, val);
                if (val != drive->cur_cyl) {
                    dev->comp |= COMP_ERR;
                    dev->sense = ERR_SEEK;
                }
            } else {
                dev->comp |= COMP_ERR;
                dev->sense = ERR_NOTRDY;
            }
            set_intr(dev);
            break;

        case CMD_SET_DRIVE_PARAMS:
            switch (dev->state) {
                case STATE_IDLE:
                    dev->state   = STATE_RDATA;
                    dev->buf_idx = 0;
                    dev->buf_len = sizeof(dprm_t);
                    dev->buf_ptr = (uint8_t *) dev->data;
                    dev->status |= STAT_REQ;
                    break;

                case STATE_RDONE:
                    params        = (dprm_t *) dev->data;
                    drive->tracks = (params->cyl_high << 8) | params->cyl_low;
                    drive->hpc    = params->heads;
                    drive->spt    = 17 /*hardcoded*/;
                    dev->status &= ~STAT_REQ;
                    set_intr(dev);
                    break;

                default:
                    break;
            }
            break;

        case CMD_WRITE_SECTOR_BUFFER:
            switch (dev->state) {
                case STATE_IDLE:
                    dev->buf_idx = 0;
                    dev->buf_len = 512;
                    dev->state   = STATE_RDATA;
                    if (dev->intr & DMA_ENA) {
                        dev->buf_ptr = dev->sector_buf;
                        timer_advance_u64(&dev->timer, HDC_TIME);
                    } else {
                        dev->buf_ptr = dev->data;
                        dev->status |= STAT_REQ;
                    }
                    break;

                case STATE_RDATA:
                    if (dev->intr & DMA_ENA) {
                        /* Perform DMA. */
                        while (dev->buf_idx < dev->buf_len) {
                            val = dma_channel_read(dev->dma);
                            if (val == DMA_NODATA) {
                                xta_log("%s: CMD_WRITE_BUFFER out of data!\n", dev->name);
                                dev->status |= (STAT_CD | STAT_IO | STAT_REQ);
                                timer_advance_u64(&dev->timer, HDC_TIME);
                                return;
                            }

                            dev->buf_ptr[dev->buf_idx] = (val & 0xff);
                            dev->buf_idx++;
                        }
                        dev->state = STATE_RDONE;
                        timer_advance_u64(&dev->timer, HDC_TIME);
                    }
                    break;

                case STATE_RDONE:
                    if (!(dev->intr & DMA_ENA))
                        memcpy(dev->sector_buf,
                               dev->data, dev->buf_len);
                    set_intr(dev);
                    break;

                default:
                    break;
            }
            break;

        case CMD_RAM_DIAGS:
            switch (dev->state) {
                case STATE_IDLE:
                    dev->state = STATE_RDONE;
                    timer_advance_u64(&dev->timer, 5 * HDC_TIME);
                    break;

                case STATE_RDONE:
                    set_intr(dev);
                    break;

                default:
                    break;
            }
            break;

        case CMD_DRIVE_DIAGS:
            switch (dev->state) {
                case STATE_IDLE:
                    if (drive->present) {
                        dev->state = STATE_RDONE;
                        timer_advance_u64(&dev->timer, 5 * HDC_TIME);
                    } else {
                        dev->comp |= COMP_ERR;
                        dev->sense = ERR_NOTRDY;
                        set_intr(dev);
                    }
                    break;

                case STATE_RDONE:
                    set_intr(dev);
                    break;

                default:
                    break;
            }
            break;

        case CMD_CTRL_DIAGS:
            switch (dev->state) {
                case STATE_IDLE:
                    dev->state = STATE_RDONE;
                    timer_advance_u64(&dev->timer, 10 * HDC_TIME);
                    break;

                case STATE_RDONE:
                    set_intr(dev);
                    break;

                default:
                    break;
            }
            break;

        default:
            xta_log("%s: unknown command - %02x\n", dev->name, dcb->cmd);
            dev->comp |= COMP_ERR;
            dev->sense = ERR_ILLCMD;
            set_intr(dev);
    }
}

/* Read one of the controller registers. */
static uint8_t
hdc_read(uint16_t port, void *priv)
{
    hdc_t  *dev = (hdc_t *) priv;
    uint8_t ret = 0xff;

    switch (port & 7) {
        case 0: /* DATA register */
            dev->status &= ~STAT_IRQ;

            if (dev->state == STATE_SDATA) {
                if (dev->buf_idx > dev->buf_len) {
                    xta_log("%s: read with empty buffer!\n",
                            dev->name);
                    dev->comp |= COMP_ERR;
                    dev->sense = ERR_ILLCMD;
                    break;
                }

                ret = dev->buf_ptr[dev->buf_idx];
                if (++dev->buf_idx == dev->buf_len) {
                    /* All data sent. */
                    dev->status &= ~STAT_REQ;
                    dev->state = STATE_SDONE;
                    timer_set_delay_u64(&dev->timer, HDC_TIME);
                }
            } else if (dev->state == STATE_COMPL) {
                xta_log("DCB=%02X  status=%02X comp=%02X\n", dev->dcb.cmd, dev->status, dev->comp);
                ret         = dev->comp;
                dev->status = 0x00;
                dev->state  = STATE_IDLE;
            }
            break;

        case 1: /* STATUS register */
            ret = (dev->status & ~STAT_DCB);
            break;

        case 2:         /* "read option jumpers" */
            ret = 0xff; /* all switches off */
            break;

        default:
            break;
    }

    return ret;
}

/* Write to one of the controller registers. */
static void
hdc_write(uint16_t port, uint8_t val, void *priv)
{
    hdc_t *dev = (hdc_t *) priv;

    switch (port & 7) {
        case 0: /* DATA register */
            if (dev->state == STATE_RDATA) {
                if (!(dev->status & STAT_REQ)) {
                    xta_log("%s: not ready for command/data!\n", dev->name);
                    dev->comp |= COMP_ERR;
                    dev->sense = ERR_ILLCMD;
                    break;
                }

                if (dev->buf_idx >= dev->buf_len) {
                    xta_log("%s: write with full buffer!\n", dev->name);
                    dev->comp |= COMP_ERR;
                    dev->sense = ERR_ILLCMD;
                    break;
                }

                /* Store the data into the buffer. */
                dev->buf_ptr[dev->buf_idx] = val;
                if (++dev->buf_idx == dev->buf_len) {
                    /* We got all the data we need. */
                    dev->status &= ~STAT_REQ;
                    if (dev->status & STAT_DCB)
                        dev->state = STATE_RDONE;
                    else
                        dev->state = STATE_IDLE;
                    dev->status &= ~STAT_CD;
                    timer_set_delay_u64(&dev->timer, HDC_TIME);
                }
            }
            break;

        case 1: /* RESET register */
            dev->sense = 0x00;
            dev->state = STATE_IDLE;
            break;

        case 2: /* "controller-select" */
            /* Reset the DCB buffer. */
            dev->buf_idx = 0;
            dev->buf_len = sizeof(dcb_t);
            dev->buf_ptr = (uint8_t *) &dev->dcb;
            dev->state   = STATE_RDATA;
            dev->status  = (STAT_BSY | STAT_CD | STAT_REQ);
            break;

        case 3: /* DMA/IRQ intr register */
#if 0
            xta_log("%s: WriteMASK(%02X)\n", dev->name, val);
#endif
            dev->intr = val;
            break;

        default:
            break;
    }
}

static void *
xta_init(const device_t *info)
{
    drive_t    *drive;
    const char *bios_rev = NULL;
    const char *fn       = NULL;
    hdc_t      *dev;
    int         c;
    int         max = XTA_NUM;

    /* Allocate and initialize device block. */
    dev = calloc(1, sizeof(hdc_t));
    dev->type = info->local;

    /* Do per-controller-type setup. */
    switch (dev->type) {
        case 0: /* WDXT-150, with BIOS */
            dev->name     = "WDXT-150";
            dev->base     = device_get_config_hex16("base");
            dev->irq      = device_get_config_int("irq");
            dev->rom_addr = device_get_config_hex20("bios_addr");
            dev->dma      = 3;
            bios_rev      = (char *) device_get_config_bios("bios_rev");
            fn            = (char *) device_get_bios_file(info, bios_rev, 0);
            max           = 1;
            break;

        case 1: /* EuroPC */
            dev->name = "HD20";
            dev->base = 0x0320;
            dev->irq  = 5;
            dev->dma  = 3;
            break;

        default:
            break;
    }

    xta_log("%s: initializing (I/O=%04X, IRQ=%d, DMA=%d",
            dev->name, dev->base, dev->irq, dev->dma);
    if (dev->rom_addr != 0x000000)
        xta_log(", BIOS=%06X", dev->rom_addr);

    xta_log(")\n");

    /* Load any disks for this device class. */
    c = 0;
    for (uint8_t i = 0; i < HDD_NUM; i++) {
        if ((hdd[i].bus_type == HDD_BUS_XTA) && (hdd[i].xta_channel < max)) {
            drive = &dev->drives[hdd[i].xta_channel];

            if (!hdd_image_load(i)) {
                drive->present = 0;
                continue;
            }
            drive->id      = c;
            drive->hdd_num = i;
            drive->present = 1;

            /* These are the "hardware" parameters (from the image.) */
            drive->cfg_spt    = (uint8_t) (hdd[i].spt & 0xff);
            drive->cfg_hpc    = (uint8_t) (hdd[i].hpc & 0xff);
            drive->cfg_tracks = (uint16_t) hdd[i].tracks;

            /* Use them as "configured" parameters until overwritten. */
            drive->spt    = drive->cfg_spt;
            drive->hpc    = drive->cfg_hpc;
            drive->tracks = drive->cfg_tracks;

            xta_log("%s: drive%d (cyl=%d,hd=%d,spt=%d), disk %d\n",
                    dev->name, hdd[i].xta_channel, drive->tracks,
                    drive->hpc, drive->spt, i);

            if (++c > max)
                break;
        }
    }

    /* Enable the I/O block. */
    io_sethandler(dev->base, 4,
                  hdc_read, NULL, NULL, hdc_write, NULL, NULL, dev);

    /* Load BIOS if it has one. */
    if (dev->rom_addr != 0x000000) {
        rom_init(&dev->bios_rom, fn,
                 dev->rom_addr, 0x2000, 0x1fff, 0, MEM_MAPPING_EXTERNAL);
    }

    /* Create a timer for command delays. */
    timer_add(&dev->timer, hdc_callback, dev, 0);

    return dev;
}

static void
xta_close(void *priv)
{
    hdc_t         *dev = (hdc_t *) priv;
    const drive_t *drive;

    /* Remove the I/O handler. */
    io_removehandler(dev->base, 4,
                     hdc_read, NULL, NULL, hdc_write, NULL, NULL, dev);

    /* Close all disks and their images. */
    for (uint8_t d = 0; d < XTA_NUM; d++) {
        drive = &dev->drives[d];

        hdd_image_close(drive->hdd_num);
    }

    /* Release the device. */
    free(dev);
}

static const device_config_t wdxt150_config[] = {
    // clang-format off
    {
        .name           = "bios_rev",
        .description    = "BIOS Revision",
        .type           = CONFIG_BIOS,
        .default_string = "rev_1",
        .default_int    = 0,
        .file_filter    = NULL,
        .spinner        = { 0 },
        .bios           = {
            {
                .name          = "Revision 1.0",
                .internal_name = "rev_1",
                .bios_type     = BIOS_NORMAL,
                .files_no      = 1,
                .local         = 0,
                .size          = 8192,
                .files         = { WD_REV_1_BIOS_FILE, "" }
            },
            {
                .name          = "Revision 2.0",
                .internal_name = "rev_2",
                .bios_type     = BIOS_NORMAL,
                .files_no      = 1,
                .local         = 0,
                .size          = 8192,
                .files         = { WD_REV_2_BIOS_FILE, "" }
            },
            { .files_no = 0 }
        },
    },
    {
        .name           = "base",
        .description    = "Address",
        .type           = CONFIG_HEX16,
        .default_string = NULL,
        .default_int    = 0x0320,
        .file_filter    = NULL,
        .spinner        = { 0 },
        .selection      = {
            { .description = "320H", .value = 0x0320 },
            { .description = "324H", .value = 0x0324 },
            { .description = ""                      }
        },
        .bios           = { { 0 } }
    },
    {
        .name           = "irq",
        .description    = "IRQ",
        .type           = CONFIG_SELECTION,
        .default_string = NULL,
        .default_int    = 5,
        .file_filter    = NULL,
        .spinner        = { 0 },
        .selection      = {
            { .description = "IRQ 5", .value = 5 },
            { .description = "IRQ 4", .value = 4 },
            { .description = ""                  }
        },
        .bios           = { { 0 } }
    },
    {
        .name           = "bios_addr",
        .description    = "BIOS Address",
        .type           = CONFIG_HEX20,
        .default_string = NULL,
        .default_int    = 0xc8000,
        .file_filter    = NULL,
        .spinner        = { 0 },
        .selection      = {
            { .description = "C800H", .value = 0xc8000 },
            { .description = "CA00H", .value = 0xca000 },
            { .description = ""                        }
        },
        .bios           = { { 0 } }
    },
    { .name = "", .description = "", .type = CONFIG_END }
// clang-format off
};

const device_t xta_wdxt150_device = {
    .name          = "WDXT-150 XTA Fixed Disk Controller",
    .internal_name = "xta_wdxt150",
    .flags         = DEVICE_ISA,
    .local         = 0,
    .init          = xta_init,
    .close         = xta_close,
    .reset         = NULL,
    .available     = NULL /*xta_available*/,
    .speed_changed = NULL,
    .force_redraw  = NULL,
    .config        = wdxt150_config
};

const device_t xta_hd20_device = {
    .name          = "EuroPC HD20 Fixed Disk Controller",
    .internal_name = "xta_hd20",
    .flags         = DEVICE_ISA,
    .local         = 1,
    .init          = xta_init,
    .close         = xta_close,
    .reset         = NULL,
    .available     = NULL,
    .speed_changed = NULL,
    .force_redraw  = NULL,
    .config        = NULL
};
